A design method for the current controller of a grid connected inverter is discussed in this disclosure. The repetitive control strategy is used, in tandem with a mu-synthesis based current controller, to attain sinusoidal reference tracking and harmonic rejection. Mu-synthesis based control is chosen to attain reference tracking in the presence of plant uncertainties. The repetitive control strategy is selected since it can reject a large number of harmonics simultaneously, while providing a clean sinusoidal current waveform to the grid, even in the presence of grid load and/or voltage distortions. The repetitive control strategy is implemented via the internal model principle. By applying mu-synthesis principles, a feedback controller that simultaneously achieves stability and tracking performance is obtained.
Legal claims defining the scope of protection, as filed with the USPTO.
1. A control system for a power inverter, where the power inverter is configured to supply power to a load, and the control system for the power inverter comprising: a plurality of output voltage sensors ( 22 ), and plurality of output current sensors ( 23 ) configured to measure output AC voltages and output AC currents of the power inverter; an input voltage sensor ( 13 ) and input current sensor ( 24 ), configured to measure input DC voltage and input DC current of the power inverter; a controller coupled to the power inverter, and being configured to: provide a control signal associated with a DC voltage reference ( 29 ), and a reactive power reference ( 30 ) to the power inverter; determine a target amplitude and target frequency for the AC output voltage ( 22 ) and AC output current ( 23 ) of the power inverter; apply a low pass filter ( 15 , 16 , 17 , 18 ) to the output power of the power inverter, where the low pass band of the filter is determined based on a target amplitude and a target frequency of the output voltage ( 22 ) and output current ( 23 ).
2. The control system of claim 1 , wherein the controller is further configured to: generate a plurality of power transistor switching pulses for the power inverter based on a target amplitude and a target frequency of the AC output voltage ( 22 ) and output current ( 23 ); provide switching pulses to the power transistors of the power inverter; applying a low pass filter to the output power of the inverter.
3. The control system of claim 2 , where the control system is further configured to: determine an output active power of the power inverter based on the input DC power provided to the power inverter by the DC power source, if the power source is a solar power source; determine an output reactive power of the power inverter based on an external reference provided by an operator, if the DC power source is a solar power source; determine the output active power of the power inverter based on an external reference provided by the operator, if the DC power source is an electro-chemical energy storage power source; determine the output reactive power of the power inverter based on an external reference provided by the operator, if the DC power source is an electro-chemical energy storage power source; calculate the output active power based on the AC output voltage ( 22 ) and AC output current ( 23 ) sensor measurements; match the output active power with an operator-provided DC voltage ( 29 ) reference using a feedback control loop; calculate the output reactive power based on the AC output voltage ( 22 ) and AC output current ( 23 ) sensor measurements; match the output reactive power with the reactive power reference using a feedback control loop.
Cooperative Patent Classification codes for this invention. Click any code to explore related patents in that topic.
February 18, 2018
October 6, 2020
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